Calcium carbide–induced derangement of hematopoiesis and organ toxicity ameliorated by cyanocobalamin in a mouse model

Background Calcium carbide (CaC2) is a chemical primarily used in the production of acetylene gas. The misuse of CaC2 to induce fruit ripening is a global challenge with a potential adverse effects to human health. Additionally, CaC2 is known to contain some reasonable amount of arsenic and phosphorous compounds that are toxic and pose a danger to human health when ingested. The current study sought to characterize CaC2 toxicity and elucidate any protective effects by cyanocobalamin (vitamin B12), a well-established antioxidant and anti-inflammatory bio-molecule. Female Swiss white mice were randomly assigned into three groups; the first group was the control, while the second group was administered with CaC2. The third group received CaC2 followed by administration of vitamin B12. The mice were sacrificed at 60 days post treatment, hematological, biochemical, glutathione assay, cytokine ELISA and standard histopathology was performed. Results CaC2 administration did not significantly alter the mice body weight. CaC2 administration resulted in a significant decrease in packed cell volume (PCV), hemoglobin (Hb), red blood cells (RBCs) and RBC indices; indicative of CaC2-driven normochromic microcytic anaemia. Further analysis showed CaC2-driven leukopenia. Evidently, vitamin B12 blocked CaC2-driven suppression of PCV, Hb, RBCs and WBCs. Monocytes and neutrophils were significantly up-regulated by CaC2. CaC2-induced elevation of aspartate aminotransferase (AST), alanine aminotransferase (ALT) and bilirubin signaled significant liver damage. Notably, vitamin B12 stabilized AST, ALT and bilirubin in the presence of CaC2, an indication of a protective effect. Histopathological analysis depicted that vitamin B12 ameliorated CaC2-driven liver and kidney injury. CaC2 resulted in the depletion of glutathione (GSH) levels in the liver; while in the brain, kidney and lungs, the GSH levels were elevated. CaC2 administration resulted in elevation of pro-inflammatory cytokines TNF-α and IFN-γ. Vitamin B12 assuaged the CaC2-induced elevation of these pro-inflammatory cytokines. Conclusions These findings demonstrate for the first time that oral supplementation with vitamin B12 can protect mice against CaC2-mediated toxicity, inflammation and oxidative stress. The findings provide vital tools for forensic and diagnostic indicators for harmful CaC2 exposure; while providing useful insights into how vitamin B12 can be explored further as an adjunct therapy for CaC2 toxicity.

Background Calcium carbide (CaC 2 ) is used in the manufacture of many compounds including acetylene gas. CaC 2 yields acetylene gas when dissolved in water. Prior studies have demonstrated that when ingested by human, acetylene produces free radicals that causes cellular and organ damage [1,2]. These CaC 2 -induced free radicals cause cellular damage and accelerate the aging process [3,4]. In addition, it also contains impurities of arsenic and phosphorous compounds that are relatively toxic to human and animals [5,6]. The growing awareness of fruit safety in regard to chemical exposure has awakened research about hazards in regard to contamination with CaC 2 and a repertoire of other chemicals used in fruit ripening process [7,8]. Furthermore, CaC 2 is inappropriately used to chemically induce fruit ripening in many countries [9]. CaC 2 , is cheap and readily available tempting farmers to harvest their fruits before maturation. Even though artificial ripeners quicken the rate of the ripening process, the nutritional quality in regard to sensory, and safety of the fruits is compromised [2]. Evidently, CaC 2 causes food contamination, gastric irritation, mouth ulcers, cerebral oedema, seizures, and changes in vital hematological and biochemical processes [2,10]. Further reports have shown that chemical substances used as artificial ripeners have negative effects on humans that include memory loss, cerebral oedema, prostate, changes in DNA and RNA [2]. It is well established that CaC 2 impacts the sensory system by limiting oxygen supply to the brain, with potential consequence of neural damage. In addition, evidence shows involvement in lung failure, renal failure, dermal diseases and heart conditions [10,11]. There is a need for detailed studies to elucidate and characterize the negative physiological and biochemical process affected by CaC 2 in humans to aid in diagnosing exposure and development of pharmaceutical intervention. Previous investigations suggest involvement of oxidative stress and inflammation in CaC 2 -driven organ damage [4]. It therefore makes sense that a potent antioxidant and antiinflammatory agent could mitigate CaC 2 toxicity. Hence cyanocobalamin also known as vitamin B 12 , a potent antioxidant and anti-inflammatory molecules, usually taken as a supplement, was investigated to determine its potential to mitigate CaC 2 toxicities. Vitamin B 12 is vital in the synthesis of red blood cells, keeping nerve cells healthy and synthesis of genetic materials. The sources of vitamin B 12 include meat, milk, fish, and shellfish [12]. Vitamin B 12 is a methyl donor precursor, naturally occurring in the diet. Previous studies have demonstrated that when combin ed with folate, vitamin B 12 down-regulated the pro inflammatory cytokines and low-grade systemic inflammation [13]. The current study sought to profile or characterize negative physiological and biochemical effects of CaC 2 exposure in a mouse model. In addition; the study sought to establish the effectiveness of vitamin B 12 in abrogating CaC 2 -induced negative effects.

Effect of calcium carbide and vitamin B 12 on body and organ weight
This study examined whether vitamin B 12 administration would restore CaC 2-induced alteration in physiological parameters by measuring changes in general body and relative organ weight. Determination of mice body weight showed a steady increase in weight of control group of mice compared to the CaC 2 supplemented group of mice ( Fig. 1). There was a marginal weight gain in the group of mice both supplemented with CaC2 and/or with vitamin B12 up to 40 days post-administration; and decreased thereafter up to 60 days post-administration. To determine if the weight change was due to alteration in organ weights, the relative organ weights were determined. This was vital in order to determine whether the effect of oral administration of CaC 2 potentiated organ injury and whether administration of vitamin B 12 could ameliorate such injury. The relative organ weight for liver, spleen, brain, lungs and kidney were unaffected upon CaC 2 exposure ( Fig. 2A-E) and a significant decrease in the weight of the heart (Fig. 2F) in the CaC 2 -exposed groups. This results suggest that exposure to CaC 2 has minimal impact on the general body weight.

The effect of calcium carbide and vitamin B 12 on packed cell volume (PCV), red blood cells (RBC) and haemoglobin (Hb)
This study aimed to investigate the modulating effect of vitamin B12 on PCV, RBC and Hb following CaC 2 exposure. The altered blood levels of PCV, RBC and Hb were measured in the blood of CaC 2 and vitamin B 12 supplemented mice. The results showed that CaC 2 significantly decreased (P < 0.0001) the levels of PCV  and Hb (C) levels were evaluated. Mean comparison was analyzed by One-way ANOVA, followed by Turkeys Post hoc test (*P ≤ 0.05; **P ≤ 0.01; ***P ≤ 0.001). n = 12. Bars presents ± SEM

Effect of calcium carbide and vitamin B 12 on red blood cell (RBC) indices
Next, this study sought to classify the type of anemia that was induced following CaC 2 exposure. Classification was done by measuring various RBC indices in the blood. There was decrease in MCV levels upon exposure to CaC 2 relative to control group of mice (Fig. 4A). Notably, vitamin B 12 supplementation restored the significant CaC 2 -driven down-regulation of the mean corpuscular hemoglobin (MHC), the mean corpuscular hemoglobin concentration (MCHC) and ded cell distribution width standard deviation (RDW-SD) ( Fig. 4B-D). However, the levels of red cell distribution width coefficient of variation (RDW-CV) (Fig. 4E) were comparable across all the groups. This result demonstrate the effect of protecting against CaC 2-induced microcytic hypochromic anemia may be linked to the antioxidant impact of vitamin B 12 .

Effect of calcium carbide and vitamin B 12 on platelets (PLT)
The levels of PLT and its indices were measured in the blood of CaC 2 exposed mice to determine if supplementation with vitamin B 12 can reverse any alteration that may be linked to thrombocytopenia. CaC 2 -induced thrombocytopenia was evident through suppression of platelet levels. Intriguingly, vitamin B 12 administration appeared to aid the recovery of platelet levels (Fig. 5A). Further analysis of the platelet indices showed that mean platelet volume (MPV) levels ( Fig. 5B) in mice exposed to calcium carbide was depleted when compared to the normal control. The platelet large cell ratio (P-LCR) was significantly reduced (P < 0.05) in mice receiving calcium carbide (Fig. 5C) when compared to either control or vitamin B 12 supplemented group of mice. This was further validated by significant reduction in the plateletcrit (PCT) and the platelet distribution width (PDW) in comparison to the control group mice (P < 0.05; Fig. 5D, E). The findings from this study demonstrate that vitamin B 12 aided the recovery of platelets in the presence of CaC 2 .

Effect of calcium carbide and vitamin B 12 on white blood cells (WBCs) and its subtypes
An attempt to elucidate the putative effect of vitamin B 12 to reverse the effects of CaC 2 -induced alteration of WBC was made. To address this question, the levels of WBC and WBC subtypes were measured in blood from the treatment group of mice. Normally, depletion of WBC numbers beyond a certain limit is an indication of leukopenia. Consistence with this, it was found out that the levels of WBCs were significantly decreased Prior experiments have already shown that CaC 2 has the capacity to induce leukopenia. Hence, this study sought to determine whether there was alteration in the composition of WBC phenotypes, in order to determine the extent of vulnerability of the mice to infections and signs of inflammation. Oral administration of CaC 2 was found to significantly increase (P < 0.01) neutrophils with reduction in the lymphocytes (Fig. 6B, C respectively). However, exposure to CaC 2 resulted in significant increase in monocyte levels with concomitant abrogation of eosinophil levels (Fig. 6D, E). Interestingly, vitamin B 12 showed the ability to prevent the CaC 2 -induced elevation of monocytes and neutrophils and restored lymphocyte and eosinophils levels. On the other hand, the levels of basophils were comparable across all the treatment groups (Fig. 6F). These results suggests that vitamin B 12 supplementation restored the CaC 2 -induced alteration in WBC and its subtypes.

Effect of calcium carbide and vitamin B 12 on the lipid profile
This study investigated whether vitamin B 12 administration could restore the effect of CaC 2-induced alteration of lipid profile by measuring the changes in the serum levels total cholesterol, high density lipoproteins and triglycerides. Results from this study further reveal that exposure of mice to CaC 2 resulted in elevation of total cholesterol levels relative to either control or vitamin B 12 administered mice (Fig. 7A). Notably, a significant decrease in high density lipoprotein (HDL) (P < 0.05) was observed in mice administered with CaC 2 (Fig. 7B). On the contrary, the levels of triglycerides were comparable across all the treatment groups (Fig. 7C). This observation indicates that vitamin B 12 was more effective in mitigating CaC 2-induced elevation of cholesterol and reduction in high density lipoprotein, may be linked to the cellular protection.

Effect of CaC 2 and vitamin B 12 on organ cellular reduced glutathione (GSH) concentration
Next we determined whether vitamin B 12 supplementation had the capacity to modulate oxidative stress following exposure of mice with CaC 2 by measuring the cellular levels of GSH in the liver, kidney, brain, spleen, lungs and heart. Reduced glutathione is one of the primary antioxidants involved in the quenching of reactive oxygen species (ROS) under abnormal physiological conditions. In the CaC 2 -treated group, there was significant decrease in the level of GSH in the liver relative to mice administered with vitamin B 12 (Fig. 8A). Supplementation with vitamin B 12 blocked suppression of the cellular GSH levels in the liver. Additionally, exposure of mice to CaC 2 resulted in a significant increase (P < 0.05) in the concentration of cellular GSH levels in the brain, kidney, lungs and spleen ( Fig. 8B-E). However, the cellular levels of in the heart were comparable across all the treatment groups ( Fig. 8F). Vitamin B 12 supplementation resulted in stabilization of GSH levels in this vital organs. These results is a clear indication of reduced oxidative stress in the presence of vitamin B 12 .

Effects of calcium carbide and vitamin B 12 on the markers of liver and kidney injury
This study determined whether vitamin B 12 supplementation would nullify CaC 2 -induced liver and kidney injury, by measuring serum levels of transaminases, total bilirubin and creatinine. Calcium carbide administration resulted in elevation of ALT and AST levels (Fig. 9A, B). Similarly, the result showed a ratio of more than 2:1 in regard to AST: ALT, indicative of liver damage (Fig. 9C).
In the presence of vitamin B 12 9D). There was a significant increase (P < 0.05) in levels of the serum creatinine among mice treated with CaC 2 . Oral administration of vitamin B 12 significantly abrogated CaC 2-induced elevation of serum creatinine levels (Fig. 9E). These results suggest that vitamin B 12 supplementation protected against CaC 2-induced liver and kidney injury is associated with anti-inflammatory properties of vitamin B 12 .

Histopathological analysis of liver and kidney
To establish presence of any deleterious effects of CaC 2 administration on the liver cyto-architecture, we performed normal standard histopathological analysis. Exposure to CaC 2 resulted in significant damage to the liver was characterized by diffuse hepatocyte swelling necrosis, and focal hemorrhages in the liver parenchyma (Fig. 10). It is noteworthy, that Vitamin B 12 administration CaC 2 assuaged CaC 2 -driven liver pathology. Furthermore, CaC 2 administration resulted in kidney damage. Specifically, the injury was characterized by the presence of cytoplasmic vacuolation of tubular epithelial cells (Fig. 10). These results suggest that administration of vitamin B 12 protected liver and kidney tissue from CaC 2 -induced damage is associated with the anti-inflammatory properties of vitamin B 12 .

Effect of calcium carbide and vitamin B 12 on cytokines
The levels of the pro-inflammatory cytokines tumor necrotic factor-alpha (TNF-α) and interferon gamma (IFN-γ), as well as the anti-inflammatory cytokine interleukin-10 (IL-10), were determined from serum samples to evaluate the ability of CaC 2 to trigger inflammation. CaC 2 markedly elevated levels of serum TNF-α and IFN-γ (P < 0.0001) (Fig. 11A, B). However, the levels of serum IL-10 were similar across the treatment groups (Fig. 11C). In the presence vitamin B 12, the elevation of serum TNF-α and IFN-γ levels was abrogated. The ratios between pro-inflammatory and anti-inflammatory cytokines established the extent of active inflammation where CaC 2 supplementation resulted in significant (P < 0.05) imbalance of both TNF-α: IL-10 ratio and IFNγ: IL-10 ratios (Fig. 11D, E). However, vitamin B 12 supplementation abrogated the CaC 2 -induced TNF-α: IL-10 imbalance. These results demonstrates the effect of protecting against CaC 2-induced inflammation can be linked to the anti-inflammatory effect of vitamin B 12 .

Discussion
Exposure to CaC 2 causes serious detrimental effects that often can trigger cancer development, food poisoning, irritation of gastral tissues and mouth ulceration, cerebral oedema and seizures [2]. Moreover, ingestion of fruits ripened with CaC 2 can cause alterations to vital physiological and biochemical processes [7]. Notably, the negative physiological and biochemical processes due to CaC 2 exposure have not been well characterized to enable diagnostic and forensic determination of exposure, as well as allow development of detoxification or treatment strategies. In this study, we demonstrate for the first time that vitamin B 12 , a potent anti-inflammatory and antioxidant, assuaged CaC 2 -induced negative physiological and biochemical effects in a mouse model. Moreover, the findings from the present study established that exposure of mice to only vitamin B 12 alone did not have any effect on both physiological, biochemical and inflammatory responses (data not provided). Notably, oral exposure to CaC 2 resulted in marginal decrease in mice body weight, though not statistically significant. Other studies have reported significant CaC 2 -induced weight gain in wistar rats [7]. The marginal alteration in body weight due to CaC 2 relative to the control indicates interference with normal physiological growth and development; which can be attributed to the impairment of biochemical processes critical for normal growth and loss of appetite. Notably, administration of vitamin B 12 did not have any impact on the general body weight of mice due to CaC 2 exposure, or that of its organs, probably due to its contribution in inhibition of adipocyte differentiation and lipid accumulation. Worthy of note is that the exposure to CaC 2 resulted in significant decrease in the relative organ weight of the heart; which was not rescued by vitamin B12 supplementation. Indeed, increased levels of AST in the current study further shows the possibility of CaC 2 -induced toxicity in other organs such as the heart; given that AST is ubiquitously distributed in other major organs of the body. Recently it has been reported that cardiovascular dysfunction due to CaC2 is associated with inflammatory mediators and oxidative stress [14]. Indeed, this findings imply that exposure to CaC 2 can result in a high risk of heart diseases This is a significant and profound phenomenon that warrants further investigations especially on the histopathological analysis of the heart. Hematopoiesis is a very significant process that warranties effective and controlled supply of a range of blood cellular constituents [15]. This study reports clear evidence for CaC 2 -driven derangement of hematopoiesis. Reduction in PCV has been associated with oxidative stress and impaired osmoregulation [8]. In the current study, a significant CaC 2 -driven decrease in PCV was noted. Decrease in PCV may be attributed to harmful effect of calcium carbide on the bone marrow, alteration of micronutrients for RBC synthesis, inhibition of erythropoietin and elevated haemolysis of the red cells due to noxious consequence. A similar study in which mice were fed on fruits ripened by CaC 2 showed reduced PCV levels [11]. Indeed, a decline in PCV is one of the key features of exposure to toxic chemicals that is associated with generation of ROS and lipid peroxidation [16]. Notably, administration of vitamin B 12 significantly stabilized the PCV levels which may be attributed to its anti-inflammatory properties. Vitamin B 12 scavenges free radicals and enhances membrane integrity by preventing lipid oxidation [17]. Indeed, lipid oxidation is interrelated with membrane fragmentation and ultimate cell death, then it is possible that vitamin B 12 protected against CaC2-driven decline in PCV levels by quenching levels of free radicals in blood thus protecting the red blood cells membrane against oxidative damage.
There was a clear CaC 2 -induced reduction in the levels of the RBCs and hemoglobin; indicative of anemia. The present findings are consistent with prior study in which expose to CaC 2 resulted in significant decrease in Red Blood Cell, Haemoglobin and Packed Cell Volume count [7]. CaC 2 driven decrease in RBCs and Hb may be due to several factors including impaired erythropoiesis, accelerated RBC lysis and microcytic or normocytic anaemia [1]. Notably, CaC 2 has been shown to obstruct elements and minerals important for erythropoiesis such as iron, folic acid and vitamin B 12 [2]. It is noteworthy that decreased haemoglobin content may result from lyses of erythrocytes, erythropenia, haemopoiesis and hindrance of erythropoietin or disruption of haemoglobin production [1]. Previous studies have shown that vitamin B 12 administration was more effective in stimulating erythropoiesis among premature infants [18]. A remarkable finding here was that administration of vitamin B 12 protected mice from CaC 2-induced suppression of RBCs and Hb levels. This results strongly supports the ameliorative effect of vitamin B 12 in CaC 2 -induced anemia observed in the current study.
Changes in RBC indices (MCV, MCH, and MCHC) constitutes a key parameter applied in the classification of anaemia. Herein, it was observed that CaC 2 -induced microcytic hypochromic anaemia, as shown by the significant reduction in the levels of MCH, MCHC and RDW-SD. Note that, contrary findings have been reported in CaC 2 exposure to rats; where RBC indices were up-regulated [7]. Once again, we demonstrated that vitamin B 12 supplementation significantly restored the levels of red cell indices. This is not surprising given that vitamin B 12 is vital for DNA synthesis and its deficiency can cause megaloblastic anaemia via abortive erythropoiesis and hyperbilirubinemias.
Platelets (PLT) play a critical role in blood clotting cascades, and are vital for preventing bleeding, support healing and have also been involved in inflammatory response and wound healing [19]. In the current study, CaC 2 significantly suppressed platelet levels, possibly through the initiation of caspase-dependent apoptosis. Reduction in platelet count may also be an indication of thrombocytopenia, whose cause may be impaired hematopoiesis; which may constitute a serious health threat to people on blood thinning therapy [20,21]. Vitamin B 12 administration appeared to aid the recovery of platelet levels. Notably, vitamin B 12 seems to stimulate thrombocytosis, possibly due to anti-inflammatory effects on vital molecules crucial for regulating platelet levels and modulate blood clotting cascades. This phenomena warrants further scrutiny.
White blood cells (WBCs) play an important role in immune function [10]. In the current study, a significant decrease in WBCs was recorded in mice administered with CaC 2 . Decrease in the WBCs also referred to as leukopenia due to CaC 2 portends serious consequences in regard to the ability to fight infections as well as disease diagnostic tests that rely on WBC levels. Leukopenia in mice administered with CaC 2 is indicative of CaC 2 -induced severe suppression of lymphoproliferative processes. Similar findings have been reported in other related studies [11]. Notably, other studies have shown contradictory findings in rats fed on fruits ripened with CaC 2 [10]. Further, studies established the ability of vitamin B 12 to prevent CaC 2 -driven down-regulation of WBCs when administered. We further evaluated the effect of CaC 2 on the various WBC subtypes (lymphocytes, monocytes, basophil and neutrophils). Oral administration of CaC 2 significantly increased the levels of neutrophils and resulted in reduced lymphocyte levels. CaC 2 -driven neutrophilia and monocytosis was noted. Notably, basophil levels were unchanged. However, in the presence of vitamin B 12 , lymphocyte levels were stabilized in mice administered with CaC 2 . Neutrophilia could be triggered due to CaC 2 -driven stress as well as inflammation and cellular damage. Neutrophilia, monocytosis and suppression of lymphocytes would definitely have detrimental implications in disease diagnosis. For example, elevation of neutrophils (neutrophilia) is characterized by laectanae infection. On the other hand, high lymphocytes and monocytes (monocytosis) traditionally signal an infection and could signal a serious disease such as leukemia. Moreover, eosinophilic is an indication for a parasitic infection, allergic reactions or cancer. The profound conclusion based on our findings is that CaC 2 -driven neutrophilia, monocytosis and suppression of lymphocytes can interfere with critical laboratory diagnostic data for serious bacterial or viral infections as well as diseases like cancer. Certainly, this phenomenon requires further scrutiny. Additionally, it is necessary to investigate this possibility in the future in order to determine the underlying mechanism through which CaC 2 mediate the derangement of hematopoiesis process within the bone marrow.
Further investigations sought to elucidate the impact of CaC 2 and vitamin B 12 on lipid metabolism. Exposure of mice to CaC 2 , resulted in significant elevation of cholesterol. Notably, a significant decrease in high density lipoprotein (HDL) was observed in mice administered with CaC 2 . On the other hand, the levels of triglycerides were comparable across the groups. Previous studies have noted contradictory findings in regard to the effect of CaC 2 on lipid metabolism. A previous study reported decreased plasma cholesterol and low-density lipoprotein (LDL) in rats fed on mangoes ripened with CaC 2 [7]. Note that HDL stimulates efflux of excessive cholesterol from outlying tissues by reverting it back to the liver for biliary elimination [22]. Elevated serum levels of cholesterol, triglycerides (TG) and low density lipoprotein (LDL) is associated with dyslipidemia [23]. In pre-clinical studies, low vitamin B 12 levels is linked to increased lipid accumulation in adipocytes that ultimately elicit dyslipidemia in mice [24]. On this basis, it can be concluded that CaC 2 significantly affect lipid metabolism, with exposure to vitamin B 12 counteracting this effect.
Glutathione (GSH) is a major antioxidant defense molecule produced in the body [25]. It is one of the most critical sources of reducing power and redox stabilization in cells [26]. Consequently, it provides first line cellular defense against free radicals. Reduced glutathione in the tissues is one of the primary antioxidants involved in the quenching of generated ROS under abnormal physiological conditions such as those induced by toxins [27,28]. Hydroxamic acid, a known toxin, disrupts the antioxidant balance in the liver and spleen at higher doses in rats [27]. For this reason, changes in cellular GSH can be utilized as a marker for oxidative stress [29]. In the current study, a significant depletion of GSH was noted in the liver. Reduced levels of GSH in body tissues is suggestive of extreme oxidative stress. Calcium carbide administration resulted in a significant increase in the concentration of cellular GSH levels in the brain, kidney and lungs. However, the cellular levels of GSH in the spleen and heart were comparable across all the treatment groups. A rise in GSH levels may be due to induction of its synthesis via a cascade of enzymatic reactions; in response to rise in oxidative stress [26,29]. On the other hand, decreased GSH may be caused by its overutilization during chronic oxidative stress due to its role as the prime intra cellular anti-oxidant [26]. Vitamin B 12 supplementation resulted in stabilization of GSH in the presence of CaC 2 in the liver, brain and kidney. This is not surprising given that Vitamin B 12 is known to prevent deleterious effects associated with oxidative tissue injury due to its anti-apoptotic and anti-oxidative functions. It is noteworthy, to mention that other previous studies have demonstrated the role of vitamin B 12 in stabilizing GSH levels [27,30]. This may attribute to the ability of vitamin B 12 to counter oxidative stress, thereby reducing the demand on GSH due to its anti-oxidant properties.
The liver is an important organ that plays a vital role in the metabolism of xenobiotics and is the primary target for CaC 2 toxicity. Therefore, during CaC2 poisoning, liver damage is unavoidable.
Moreover, ALT and AST are important liver enzymes, whose levels in serum is an indicator of liver pathology. In the current study, ALT and AST levels were elevated upon exposure of mice to CaC 2 , but were stabilized upon administration of vitamin B 12 . Additional investigations on the liver showed CaC 2 -driven elevation of bilirubin. A bilirubin test is vital in diagnosing liver damage since bilirubin is a bile pigment formed from the breakdown of haemoglobin in RBCs. Increased bilirubin levels is indicative of hepatobiliary disorder with blockage of flow of bile through the bile duct [7]. Perhaps due to its antioxidant capabilities, vitamin B 12 stabilized levels of AST, ALT and bilirubin. This a clear evidence for Vitamin B 12 -driven hepatocellular protection from CaC 2 -driven liver injury [31].
Additional investigations focused on the integrity of kidney function in the presence of CaC 2 and vitamin B 12 . We demonstrate that CaC 2 driven renal injury was ameliorated by administration of vitamin B 12 . Elevated creatinine levels suggest a reduction in the glomerular filtration rate; indicative of kidney function impairment. Similar findings have been noted in rat fed with CaC 2 -ripened mango [1]. Moreover, elevated creatinine levels is associated with reduced glomerular filtration, impaired elimination of waste products with potential kidney swelling, inflammation, and necrotic cell damage [16]. Once again, oral administration of vitamin B 12 abrogated CaC 2-induced rise in serum creatinine levels is linked to its anti-inflammatory properties.
Cytokines are biologically active proteins that mediate vital intercellular communication in the immune system and are secreted by different immune cell types. In addition, they participate in host defense, inflammatory and tissue repair activities [32,33]. Pro-inflammatory cytokines are produced by activated macrophages effector cells that participated in adaptive immune system and play a significant role in exacerbation of inflammatory processes. Consequently, interferon gamma (IFN-γ) and tumor necrosis factor alpha (TNF-α) are critical in fighting infections, and ultimately for cell survival mechanisms. In the current study, the levels of the pro-inflammatory cytokines tumor necrotic factor-alpha (TNF-α) and interferon gamma (IFN-γ), as well as the anti-inflammatory cytokine interleukin-10 (IL-10), were determined from serum samples to evaluate the ability of CaC 2 to trigger inflammation. CaC 2 supplementation resulted in markedly augmented levels of serum TNF-α and IFN-γ. Ordinarily, cytokines work in synergy with IFN-γ, and stimulates migration of immune cells to infection sites, leading to granuloma development, capable of regulating the immune response. The functions of IFN-γ in macrophage activation and stimulation of the antigen presentation cascades is well established [33,34]. In the presence of vitamin B 12 , CaC 2 -driven elevation of serum TNF-α was blocked.
Anti-inflammatory cytokines such as interleukin 10 (IL-10), are immunoregulatory molecules that regulate the pro-inflammatory cytokine reaction. IL-10 is produced by leukocytes and is associated with inflammatory and autoimmune responses [35]. Furthermore, IL-10 exerts anti-inflammatory properties by inhibiting transcription factor; consequently targeting antigenpresenting cells and lymphocytes [32,36]. Our findings demonstrated a CaC 2 -induced elevation of the pro-inflammatory cytokines, indicative of inflammation.
Vitamin B 12 play a critical and vital role in the proper function of immune system chiefly as an immune-modulator [37]. Specifically, it has been observed that individuals who are deficient of Vitamin B 12 have low levels of CD8+ T cells and impaired activity of NK cells [38]. Indeed, lambs put on vitamin B 12 deficient diet were found to suffer most from Mycobacterium paratuberculosis due to low lymphoblastic proliferation response further highlighting the significance of vitamin B 12 as an immunestimulator [39]. Moreover, vitamin B 12 has been reported to favor both humoral and cellular immunity by increasing the levels of serum IgG, IgA, and IgM [38].
It is worth noting that vitamin B 12 may have had an immunomodulatory effect that attenuated CaC 2 toxicity driven by inflammation. Moreover, Vitamin B 12 reduces homocysteine levels and inflammation hence regulating production of TNF-alpha. Note that vitamin B 12 has also been adversely linked to pro-inflammatory cytokines and low-grade systemic inflammation in some studies [13].
Abnormal and continuous secretion with concomitant accumulation of ROS during CaC 2 metabolism is linked with aggravation in organ toxicities. This study further investigated the effect of CaC 2 through histopathological analysis of the liver and kidney to support biochemical analysis data. Exposure to CaC 2 resulted in significant damage to the liver. The liver injury was characterized by diffuse hepatocyte swelling, necrosis, and focal hemorrhages in liver parenchyma. The cytoplasm of the hepatocytes appeared normal with basophilic nucleus. Hepatocytes appeared apoptotic and shrunken. Some of the degenerating cells were shrunken and looked like minute, structure-less, hyaline masses. Vitamin B 12 administration exposure assuaged the CaC 2 -induced tissue and hepato-cellular damage.
The kidney is an essential organ controlling vital physiological and biochemical processes such as homeostasis, detoxification and elimination of lethal metabolites and drugs [40]. Histopathological analysis of the kidney revealed evidence for CaC 2 -induced kidney injury, characterized by the presence of cytoplasmic vacuolation of tubular epithelial cells. It can only be concluded that kidney injury and nephrosis occurred due to calcium carbide and/or its metabolites. The findings are consistent with studies conducted on proliferative and nonproliferative lesions of the rat and mouse urinary systems due to calcium carbide on rat tissues [4]. It was notable that administration of vitamin B 12 after CaC 2 protected kidney tissue from CaC 2 -induced damage. The association between vitamin B 12 and reduced inflammation and homocysteine which is associated with oxidative stress has widely been reported by a number of studies [41,42]. The capacity of vitamin B12 to be well distributed in extracellular and cytosolic spaces is fundamental in its efficiency against CaC 2 toxicity. Further research will be needed to further characterize CaC 2 -toxicity in order to elucidate the apparent molecular processes responsible for the ability of vitamin B 12 to confer protection from CaC 2 toxicity in mice and further determine the residue levels of CaC 2 toxicity. Moreover, there is need for future studies to look at the impact of CaC 2 exposure on male mice and compare the findings from studies on female mice to see whether there exist any apparent differences in terms of sex.

Conclusions
In this study we demonstrated a clear pattern of CaC 2 -induced interference with hematopoiesis, major organ function (liver, kidney), immune function, and oxidation status. A clear protective effect against these CaC 2 -driven assault by cyanocobalamin has been established. With further studies, a mitigation strategy against CaC 2 toxicity using cyanocobalamin holds great promise.

Ethical statement
Experimental procedures and protocols involving use of mice adhered to International standards on laboratory animal use with strict adherence of the 3R rules and the ARRIVE checklist for handling animal research. The ethical clearance governing the use of mice in this study was approved by Institutional review for approval Committee (IRC) of the Institute of Primate Research Karen, Kenya (ISERC/08/2017).

Experimental animals
In this study 5-6-week-old female Swiss white mice were purchased were from Biotechnology Research Institute Muguga, Kenya and were left to acclimatize for one week before the start of the experiment. Mice were housed in standard clean cages under a controlled room temperature of 21-25 °C and a 12 h light/dark cycle. Mice had access to clean water ad libitum and mice were fed on standard chow diet (Unga Group Plc., Nairobi, Kenya).

Experimental design
Mice were randomly allocated into three treatment groups (n = 12). The treatments were administered orally at a dose of (100 mg/kg) Calcium carbide and (6 mg/kg) vitamin B 12 all purchased from Sigma-Aldrich (Sigma-Aldrich Co., St. Louis, MO, USA). The calcium carbide sub-acute dosage was informed by previous findings that 500 mg/kg induced damage to vital organs [43]. A dose of 6 mg/kg was used for Vitamin B 12 treatment in this study based on previous findings that 6 mg/kg enhance protection against xenobiotic induced toxicity [44]. Control group of mice received distilled water (vehicle), group two received calcium carbide dissolved in distilled water daily for 60 days, group three was administered with vitamin B 12 after exposure to calcium carbide daily for 60 days. Mice were sacrificed at 60 days' post treatment.

Sample collection
Mice from each group were sacrificed as per the experimental design (60 days post treatment) by administration of ketamine (50 mg/ml) and xylazine (100 mg/ml) (Merck KGaA., Darmstadt, Germany) in a ratio of 4:1 through intramuscular injection to euthanize the mice. Anaesthetized mice were intracardially perfused with sterile phosphate buffer solution (PBS) to clear both non-adhering and adhering blood lymphocytes and erythrocytes. Brain, lungs, heart, kidney, liver and spleen samples were extracted and placed in 1.5 µl eppendorf tubes and collagenase (Sigma-Aldrich Co., St. Louis, MO, USA).

Determination of body and organs weights
Change in general body weight was determined daily throughout the experimental period. After 60 days, mice from each group were anesthetized with 0.02 ml Ketamine and dissected to obtain liver, brain, lungs, heart, kidney and spleen. Analytical electronic balance (Mettler PM34, DoltaRange ® ., Mumbai, India) was used to measure the weight of the extracted organs. Individual relative organ weight were determined by dividing each animal's organ weight by their body weight multiplied by 100%.

Determination of haematological indices and biochemical markers
For hematological analysis, blood samples were obtained intra-cardially and were placed in EDTA tubes while blood for biochemical assay was collected in non-heparinized tubes and then they were centrifuged to obtain serum. Full blood hemogram was analyzed using automated Benchman Coulter counter (Benchman, Indianapolis, USA). Blood was left to stand at room temperature then centrifuged at 10,000 rpm for 5 min at 4 °C. Serum obtained was used to measure the levels of aspartate amino transferase (AST), alanine amino transferase (ALT), total bilirubin (TBIL) and creatinine were measured using automated analyzer (COBAS Integra-400 plus analyzer, Basel, Switzerland).

Glutathione (GSH) assay determination
Snap frozen whole kidney, spleen, lungs, heart, brain and liver were homogenized using ice water at (4 °C) in 0.5 ml of 0.25 M sucrose, 5 mM Hepes-Tris, pH 7.5, with protease inhibitor cocktail whose concentration was 100% (w/v). Cellular levels of GSH (Sigma-Aldrich Co., St. Louis, MO, USA) was determined by employing the method of Griffith [45]. Briefly the cellular GSH from various organs was assessed by mixing the organ homogenates 5.5′ Dithiobis-2-nitrobenzoic acid (DNTB), with the absorbance of the resulting reaction product measured at 412 nm using a multi-detection microtitre plate reader (Thermo Fisher Scientific Inc., Wilmington, MA, USA).

Enzyme linked immunoassay (ELISA)
ELISA secreted cytokine levels in serum for TNF-α, IFN-γ and IL-10 EISA kits (Thermo Fisher Scientific Inc., California, USA) were employed according to the manufacturer's protocols. Briefly, High binding ELISA plates were coated with capture antibody and incubated at 4 °C overnight and washed 3 times using washing buffer followed by blocking using ELISA diluent and incubated for 1 h at room temperature. The plates were then washed followed by additional of standard cytokines and samples to the appropriate wells. The plates were then incubated for 2 h at room temperature, and then washed after which detection antibody was added and then incubated for 1 h at room temperature. The plates were then washed and then secondary antibodies were added and the plates were incubated for 1 h, after which they were washed and the substrate was added and incubated for 15 min at room temperature. Serum levels of these cytokine were quantified by ELISA micro-titer reader (Thermo Fisher Scientific Inc., Wilmington, MA, USA) at absorbance of 450 nm.

Standard histopathology for the liver and kidney
Liver and kidney were harvested and rinsed in phosphate buffered saline and then fixed in 4% formaldehyde. Processing was done by dehydration at different concentration of alcohol and embedding them in paraffin wax. The tissues were then sectioned in thickness of 5 μm using HM 310 rotary microtome followed by staining of sectioned tissues with haematoxylin and eosin (H&E, Sigma-Aldrich Co.). The tissues sections were then analyzed by employing the use of compound microscope for pathological lesions.

Statistical analysis
One-way ANOVA was used to compare the treatment groups with controls. For internal comparisons, Turkey's post-hoc test was used. The results were given as a ± SEM with significance set at P < 0.05. Statistical analysis was done using GraphPad prism software package (Version 5.0).